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Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector

The planned HL-LHC (High Luminosity LHC) in 2025 is being designed to maximise the physics potential of the LHC through a sizeable increase in the luminosity, reaching 1x1035cm-2s-1 after 10 years of operation. A consequence of this increased luminosity is the expected radiation damage at a integrat...

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Autores principales: Blue, Andrew, ATLAS Collaboration
Lenguaje:eng
Publicado: 2016
Materias:
Acceso en línea:http://cds.cern.ch/record/2230814
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author Blue, Andrew
ATLAS Collaboration
author_facet Blue, Andrew
ATLAS Collaboration
author_sort Blue, Andrew
collection CERN
description The planned HL-LHC (High Luminosity LHC) in 2025 is being designed to maximise the physics potential of the LHC through a sizeable increase in the luminosity, reaching 1x1035cm-2s-1 after 10 years of operation. A consequence of this increased luminosity is the expected radiation damage at a integrated luminosity of 3000fb-1, requiring the tracking detectors to withstand hadron fluencies to over 1x1016 1 MeV neutron equivalent per cm2. With the addition of increased readout rates, a complete re-design of the current ATLAS Inner Detector (ID) is being developed as the Inner Tracker (ITk), which will consist of both strip and pixelated silicon detectors. The silicon strip tracker exploits the concept of modularity. Fast readout electronics, deploying 130nm CMOS front-end electronics is glued on top of a silicon sensor. These so-called modules are glued on carbon structures and will span about 200m^2 of active area. A broad R&D program is ongoing to develop and prototype many detector components. The modules are extensively tested electronically and recent tests of the prototype strip sensors and associated binary readout electronics have been performed at the DESY II testbeam of 3-6 GeV electrons. The DURANTA telescope with an additional pixel layer was used to improve timing resolution. Results will be shown on the tracking performance of both silicon sensors for the central and forward region of the future silicon strip tracker. An irradiation programme was subsequently conducted on both module components (ASICs, sensors and hybrids) and a full central region module, with devices irradiated with both X-rays (up to 10 MRad) and hadrons (~3x10^15 p/cm2). Results will then be shown comparing the performance of the modules before and after irradiation, using data obtained from both lab tests and testbeam.
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language eng
publishDate 2016
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spelling cern-22308142019-09-30T06:29:59Zhttp://cds.cern.ch/record/2230814engBlue, AndrewATLAS CollaborationTestbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking DetectorParticle Physics - ExperimentThe planned HL-LHC (High Luminosity LHC) in 2025 is being designed to maximise the physics potential of the LHC through a sizeable increase in the luminosity, reaching 1x1035cm-2s-1 after 10 years of operation. A consequence of this increased luminosity is the expected radiation damage at a integrated luminosity of 3000fb-1, requiring the tracking detectors to withstand hadron fluencies to over 1x1016 1 MeV neutron equivalent per cm2. With the addition of increased readout rates, a complete re-design of the current ATLAS Inner Detector (ID) is being developed as the Inner Tracker (ITk), which will consist of both strip and pixelated silicon detectors. The silicon strip tracker exploits the concept of modularity. Fast readout electronics, deploying 130nm CMOS front-end electronics is glued on top of a silicon sensor. These so-called modules are glued on carbon structures and will span about 200m^2 of active area. A broad R&D program is ongoing to develop and prototype many detector components. The modules are extensively tested electronically and recent tests of the prototype strip sensors and associated binary readout electronics have been performed at the DESY II testbeam of 3-6 GeV electrons. The DURANTA telescope with an additional pixel layer was used to improve timing resolution. Results will be shown on the tracking performance of both silicon sensors for the central and forward region of the future silicon strip tracker. An irradiation programme was subsequently conducted on both module components (ASICs, sensors and hybrids) and a full central region module, with devices irradiated with both X-rays (up to 10 MRad) and hadrons (~3x10^15 p/cm2). Results will then be shown comparing the performance of the modules before and after irradiation, using data obtained from both lab tests and testbeam.ATL-ITK-SLIDE-2016-853oai:cds.cern.ch:22308142016-11-07
spellingShingle Particle Physics - Experiment
Blue, Andrew
ATLAS Collaboration
Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector
title Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector
title_full Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector
title_fullStr Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector
title_full_unstemmed Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector
title_short Testbeam Results from Pre and Post Irradiated Modules for the Upgrade of the ATLAS Strip Tracking Detector
title_sort testbeam results from pre and post irradiated modules for the upgrade of the atlas strip tracking detector
topic Particle Physics - Experiment
url http://cds.cern.ch/record/2230814
work_keys_str_mv AT blueandrew testbeamresultsfrompreandpostirradiatedmodulesfortheupgradeoftheatlasstriptrackingdetector
AT atlascollaboration testbeamresultsfrompreandpostirradiatedmodulesfortheupgradeoftheatlasstriptrackingdetector